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Friday, November 7, 2014

Too Tired to Practice? Ask a GPS Device

As reported by ABC NewsNebraska's Tommy Armstrong Jr. was running play after play during a preseason practice and was beginning to wear down in the heat.

He could have asked for a break, but he didn't have to. An assistant strength coach who was keeping electronic tabs on Armstrong could tell by looking at his laptop that the quarterback was fatigued. Armstrong was ordered to the sideline.
"Dial it down," he was told.
Armstrong had just entered the "red zone" — and not the kind that extends from the end zone to the 20-yard line. This "red zone" meant Armstrong — who was wearing a tracking device relaying biomechanical data to the staffer's laptop in real time — was overexerting himself and at greater risk for injury.
It's one of the features of technology being used by about 30 college football teams and 15 NFL teams to monitor the movements and physical output of players during conditioning, practices and games.
The Australia-based company Catapult developed the system about eight years ago. Rugby and soccer teams were among the first to use it. Football teams in the United States began signing on with Catapult three years ago, and several hockey and basketball teams have followed.
"You build a portfolio of data on each player so over a period of time you can tell when they're wearing down, do they need an extra rest, do they need a day off, all those things," Tennessee coach Butch Jones said. "The most important thing is what you do throughout the week to get them ready to perform at their peak, at their optimal level, come game day."
At Nebraska, the top 50 football players slip a monitor weighing about 3 ounces into a pouch in the back of the tight-fit shirts they wear under their shoulder pads. Head strength coach James Dobson said it's too expensive to track all of the Huskers' 130 players. As it is, Nebraska will pay Catapult more than $363,000 over three years to rent equipment.
Each monitor includes a GPS device and other sensors that measure hundreds of variables per second, many of them hard to pronounce.
Some of the basic metrics: how far and fast did the player travel during a practice or game, his rate of acceleration, how many times he went right vs. left and whether he moved faster when he went one way or the other. The monitor is so sensitive that it can detect even a slight change in a player's gait, which can be a sign of fatigue or injury.
Data collected is put into an algorithm developed by Catapult, and the result is a number called "player load." The load is a number that varies depending on a player's position, but the average in college football would be about 350, said Catapult sports performance manager Ben Peterson. The higher a player's number goes, the greater his exertion.
A baseline is established for each player, and his readings can be monitored in real time.
"On certain days you have to be in certain zones," said Armstrong, the Nebraska quarterback. "If you go over that, they tell you, 'Hey, yesterday you were in the red, so make sure you're not today.' If you are in the red zone, you take a few series off."
Under NCAA rules, Catapult data cannot be looked at in real time during games because it could provide a competitive advantage if one team is using the system and the other is not.
Peterson said college teams using the system have reported an average of a 27-percent decrease in soft-tissue injuries.
When an athlete does get hurt, sports medicine personnel can use Catapult data to manage his recovery. For instance, if an injured wide receiver were able to reach only 70 percent of his maximum acceleration or speed, it would show he has a ways to go before he's ready to play in a game. The data also could be used to establish points of emphasis in a hurt athlete's rehabilitation protocol.
Alabama coach Nick Saban said he looks at player load readings to see which players are working as hard as they can and, conversely, to identify ones who aren't. Saban said players who know they're going to play on Saturdays tend to give maximum effort all the time, but that's not necessarily the case for those who aren't as likely to play.
Saban said it's telling to track defensive backs.
"When they're covering a good receiver, their numbers are higher," Saban said. "When they're covering a guy who's not as fast, they're not as good."
Tennessee safety Brian Randolph said the technology helps coaches put players in the best position for success.
"They don't want to overwork us. It shows that they care," Randolph said. "They definitely tell you when you've had a lot of reps or when you have a lot of mileage on your legs from the day before, so they tell you to get in the cold tub and get extra recovery."

Thursday, November 6, 2014

A Brain-Inspired Chip Takes to the Sky

As reported by MIT Technology Review: There isn’t much space between your ears, but what’s in there can do many things that a computer of the same size never could. Your brain is also vastly more energy efficient at interpreting the world visually or understanding speech than any computer system.

That’s why academic and corporate labs have been experimenting with “neuromorphic” chips modeled on features seen in brains. These chips have networks of “neurons” that communicate in spikes of electricity (see “Thinking in Silicon”). They can be significantly more energy-efficient than conventional chips, and some can even automatically reprogram themselves to learn new skills.

Now a neuromorphic chip has been untethered from the lab bench, and tested in a tiny drone aircraft that weighs less than 100 grams.

In the experiment, the prototype chip, with 576 silicon neurons, took in data from the aircraft’s optical, ultrasound, and infrared sensors as it flew between three different rooms.

The first time the drone was flown into each room, the unique pattern of incoming sensor data from the walls, furniture, and other objects caused a pattern of electrical activity in the neurons that the chip had never experienced before. 

That triggered it to report that it was in a new space, and also caused the ways its neurons connected to one another to change, in a crude mimic of learning in a real brain. Those changes meant that next time the craft entered the same room, it recognized it and signaled as such.

The chip involved is far from ready for practical deployment, but the test offers empirical support for the ideas that have motivated research into neuromorphic chips, says Narayan Srinivasa, who leads HRL’s Center for Neural and Emergent Systems. “This shows it is possible to do learning literally on the fly, while under very strict size, weight, and power constraints,” he says.

The drone, custom built for the test by drone-maker company Aerovironment, based in Monrovia, California, is six inches square, 1.5 inches high, and weighs only 93 grams, including the battery. HRL’s chip made up just 18 grams of the craft’s weight, and used only 50 milliwatts of power. That wouldn’t be nearly enough for a conventional computer to run software that could learn to recognize rooms, says Srinivasa.

The flight test was a challenge set by the Pentagon research agency DARPA as part of a project under which it has funded HRL, IBM, and others to work on neuromorphic chips. One motivation is the hope that neuromorphic chips might make it possible for military drones to make sense of video and sensor data for themselves, instead of always having to beam it down to earth for analysis by computers or humans.

Prototypes made under DARPA’s program—like HRL’s—have delivered promising results, but much work remains before such technology can perform useful work, says Vishal Saxena, an assistant professor working on neuromorphic chips at Boise State University. “The biggest challenge is identifying what the applications will be and developing robust algorithms,” he says.

Researchers also face a chicken-and-egg scenario, with chips being developed without much idea of what algorithms they will run and algorithms being written without a firm idea of what chip designs will become established. At the same time, neuroscientists are still discovering new things about how networks of real brain cells work on information. “There’s a lot of work to be done collectively between circuit and algorithm experts and the neuroscience community,” says Saxena.

Still, HRL’s owners, GM and Boeing, are already considering how they might commercialize the technology, says Srinivasa. One option could be to use neuromorphic chips to build a degree of intelligence into the sensors increasingly found in cars, planes, and other systems.

Wednesday, November 5, 2014

Treating Ebola: The Bluetooth Method

As reported by National Geographic: Before they set a toe into the concrete-walled isolation room, the doctors and nurses become fortresses unto themselves: face shields, of course, but respirators, too, plus three layers of gloves on each hand, duct-taped to their sleeves. Nurses watch over a webcam to keep them on protocol, and Bluetooth stethoscopes relay heart data directly to a remote location—no ear canal exposure required.
Call it the no-touch approach to medicine. And it's the little-heralded reason that a hospital in Nebraska, of all places, has emerged as a leader in the stateside fight against Ebola. Already, it's brought two Ebola patients to recovery and prevented transmission to health care providers. 

The Centers for Disease Control and Prevention has held up the hospital as a model for others.

All around the world, of course, the health care workers who've been treating the terrifying disease avoid skin-to-skin contact with patients and use a battery of protective equipment, like gloves and air-filtering PAPR suits. But Nebraska Medicine, near downtown Omaha, has taken protection to a whole new frontier—and into the slightly eerie field of hands-free medicine. If successful, the approach could have implications for medical practice, even beyond Ebola, especially as the burgeoning field of telehealth takes off. (The U.S. telehealth market could grow more than 50 percent annually through 2018, Forbes reports.)

The challenge is to harness technology's protective power without jettisoning the bedside manner, a key to healing, Nebraska health care practitioners acknowledge. They're navigating the trade-offs with computer screens that display "almost life-size" images, said Nebraska Medicine lead nurse Kathleen Boulter. And although providers remain hidden beneath layers of latex and paper, their patients have surprised them with an ability to recognize them by their eyes. "A lot of emotion is expressed by our eyes," she said.

And so far, the hospital has a 100 percent success rate on Ebola. Its first Ebola patient, 51-year-old missionary Dr. Rick Sacra, stayed for nearly three weeks before his release. On Oct. 22, the hospital discharged its second patient, NBC freelance cameraman Ashoka Mukpo, 33, after a roughly two-week stay, said Boulter.


So how does Nebraska Medicine work? It starts with a secured entrance. To limit traffic in and out of the isolation room—and the risk of spreading disease—it uses the Vidyo videoconferencing platform. The isolation room houses a webcam-equipped computer connected to the front desk, the biocontainment unit's conference rooms and providers' offices outside the unit. And inside the isolation room, providers can request a second opinion or order supplies without ever leaving. "If something's going on, we know right away," Boulter said.

Traditional stethoscopes also pose a huge contamination risk, medical professionals say, because they require practitioners to lodge earpieces into their ear canals. Tech, of course, has found a way around this. The 3M Littmann Electronic Stethoscope looks much like a regular stethoscope, but its Bluetooth capabilities allow Nebraska Medicine providers to take their ears out of the equation. Instead, a sensor goes onto the patient's chest. A USB dongle, connected to the computer in the isolation room, establishes a Bluetooth connection with a remote computer. Providers outside can listen to a patient's heart and lung sounds in real time. They can even tell health care workers inside the isolation room to reposition the sensor.
Another stethoscope used by Nebraska Medicine is the Thinklabs One Digital Stethoscope. Its high sound quality allows health care workers to wear earpieces over their surgical caps, eliminating ear-canal exposure. They slip them on just before entering the isolation room and plug them into a hockey puck-sized sensor—equipped with a volume-control module—that picks up sounds from the patient's chest. Providers chuck the earpieces into the hazardous waste bin when they doff their protective gear.

Meanwhile, devices that monitor pulse and other vital signs upload measurements to the patient's electronic health record. And a wireless-capable X-ray allows nurses to send images directly to radiologists, skipping the step of transporting bulky film cassettes to the medical imaging department for processing.

Behind the no-touch push is Nebraska Medicine's information technology department, which is "robust across all units, not just biocontainment," Boulter said. "Even on regular floors, nurses have laptops on them" and rely on the same wireless X-rays. And the Center for Medicare & Medicaid Innovation awarded the hospital a $10 million telehealth grant in July.

And while other hospitals have embraced telehealth too, practitioners hope the healing touch is here to stay. "There are times when something as simple as holding a patient or family member's hand conveys calmness, caring, reduces fear. ... I don't believe the effect of a human touch is something that can be replaced," Boulter said.

Even the hospital's telehealth guru, Kyle Hall, agrees: "[I]t's still about a human diagnosing the patient."

New Clock May Redefine Time As We Know It

Strontium atoms floating in the center of this photo are the heart of the world's most precise clock.  The clock
is so exact that it can detect tiny shifts in the flow of time itself.
As reported by NPR: "My own personal opinion is that time is a human construct," says Tom O'Brian. O'Brian has thought a lot about this over the years. He is America's official timekeeper at the National Institute of Standards and Technology in Boulder, Colorado.

To him, days, hours, minutes and seconds are a way for humanity to "put some order in this very fascinating and complex universe around us."

We bring that order using clocks, and O'Brian oversees America's master clock. It's one of the most accurate clocks on the planet: an atomic clock that uses oscillations in the element cesium to count out 0.0000000000000001 (1x10-16) second at a time. If the clock had been started 300 million years ago, before the age of dinosaurs began, it would still be keeping time — down to the second. But the crazy thing is, despite knowing the time better than almost anyone on Earth, O'Brian can't explain time.

"We can measure time much better than the weight of something or an electrical current," he says, "but what time really is, is a question that I can't answer for you."

Maybe its because we don't understand time, that we keep trying to measure it more accurately. But that desire to pin down the elusive ticking of the clock may soon be the undoing of time as we know it: The next generation of clocks will not tell time in a way that most people understand.

The New Clock
At the nearby University of Colorado Boulder is a clock even more precise than the one O'Brian watches over. The basement lab that holds it is pure chaos: Wires hang from the ceilings and sprawl across lab tables. Binder clips keep the lines bunched together.

In fact, this knot of wires and lasers actually is the clock. It's spread out on a giant table, parts of it wrapped in what appears to be tinfoil. Tinfoil?

"That's research grade tinfoil," says Travis Nicholson, a graduate student here at the JILA, a joint institute between NIST and CU-Boulder. Nicholson and his fellow graduate students run the clock day to day. Most of their time is spent fixing misbehaving lasers and dealing with the rats' nest of wires. ("I think half of them go nowhere," says graduate student Sara Campbell.)

At the heart of this new clock is the element strontium. Inside a small chamber, the strontium atoms are suspended in a lattice of crisscrossing laser beams. Researchers then give them a little ping, like ringing a bell. The strontium vibrates at an incredibly fast frequency. It's a natural atomic metronome ticking out teeny, teeny fractions of a second.

This new clock can keep perfect time for 5 billion years.

"It's about the whole, entire age of the earth," says Jun Ye, the scientist here at JILA who built this clock. "Our aim is that we'll have a clock that, during the entire age of the universe, would not have lost a second."

But this new clock has run into a big problem: This thing we call time doesn't tick at the same rate everywhere in the universe. Or even on our planet.

Time Undone
Right now, on the top of Mount Everest, time is passing just a little bit faster than it is in Death Valley. That's because speed at which time passes depends on the strength of gravity. Einstein himself discovered this dependence as part of his theory of relativity, and it is a very real effect.

The world's most precise atomic clock is a mess to look at. But it can tick for billions of years without losing a second.The relative nature of time isn't just something seen in the extreme. If you take a clock off the floor, and hang it on the wall, Ye says, "the time will speed up by about one part in 1016."

The world's most precise atomic clock is a mess to look at. But it can tick for billions of years without losing a second.

That is a sliver of a second. But this isn't some effect of gravity on the clock's machinery. 

Time itself is flowing more quickly on the wall than on the floor. These differences didn't really matter until now. But this new clock is so sensitive, little changes in height throw it way off. Lift it just a couple of centimeters, Ye says, "and you will start to see that difference."

This new clock can sense the pace of time speeding up as it moves inch by inch away from the earth's core.

That's a problem, because to actually use time, you need different clocks to agree on the time. Think about it: If I say, 'let's meet at 3:30,' we use our watches. But imagine a world in which your watch starts to tick faster, because you're working on the floor above me. Your 3:30 happens earlier than mine, and we miss our appointment.

This clock works like that. Tiny shifts in the earth's crust can throw it off, even when it's sitting still. Even if two of them are synchronized, their different rates of ticking mean they will soon be out of synch. They will never agree.

The world's current time is coordinated between atomic clocks all over the planet. But that can't happen with the new one.

"At this level, maintaining absolute time scale on earth is in fact turning into nightmare," Ye says. This clock they've built doesn't just look chaotic. It is turning our sense of time into chaos.
Ye suspects the only way we will be able to keep time in the future is to send these new clocks into space. Far from the earth's surface, the clocks would be better able to stay in synch, and perhaps our unified sense of time could be preserved.

But the NIST's chief timekeeper, Tom O'Brian, isn't worried about all this. As confusing as these clocks are, they're going to be really useful.

"Scientists can make these clocks into exquisite devices for sensing a whole bunch of different things," O'Brian says. Their extraordinary sensitivity to gravity might allow them to map the interior of the earth, or help scientists find water and other resources underground.

A network of clocks in space might be used to detect gravitational waves from black holes and exploding stars.

They could change our view of the universe.

They just may not be able to tell us the time.

Tuesday, November 4, 2014

GPS and Relativity

As reported by GPSWorld: An educational video by the Perimeter Institute of Theoretical Physics shows how GPS, a navigational tool that can pinpoint your location to within a few meters, incorporates a number of effects from Einstein’s theory of relativity.


Special relativity effects include the speed of the GPS satellites (14,000km/hr), which can cause the atomic clocks on-board the satellites to register time about 7 microseconds/day slower than on earth.  General relativistic effects include the reduced gravity environment that the satellites inhabit at about 20,000km above the earth's surface which causes the clocks to run about 45 microseconds a day faster than they do on earth.  The overall effect is a +38 microseconds/day increase in measured time which is then compensated for at the satellites.


Monday, November 3, 2014

The Plane Crash That Gave Americans GPS

As reported by The Atlantic: On the first day of September in 1983, the Soviet Union shot down a plane. Its military officers thought it was a spy plane, they said later. But it was not: It was a passenger jet, Korean Air Lines Flight 007, and the 269 people on the plane all died.

The flight had originated in New York; one of the passengers was a U.S. congressman. At first, the Soviet Union wouldn't even admit its military had shot the plane down, but the Reagan administration immediately started pushing to establish what had happened and stymie the operations of the Soviet Aeroflot airline. President Reagan also made a choice that, while reported at the time, was not the biggest news to come out of this event: He decided to speed up the timeline for civilian use of GPS.

The U.S. had already launched into orbit almost a dozen satellites that could help locate its military craft, on land, in the air, or on the sea. But the use of the system was restricted. (It was meant, for instance, to help powerful weapons hit their targets—it wasn't the sort of tool governments usually want to make publicly available.) Now, Reagan said, as soon as the next iteration of the GPS system was working, it would be available for free.

It took more than $10 billion and until over 10 years for the second version of the U.S.'s GPS system to come fully online. But in 1995, as promised, it was available to private companies for consumer applications. Sort of. The government had built in some protection for itself—"selective availability," which reserved access to the best, most precise signals for the U.S. military (and anyone it chose to share that power with).

It didn't take long, though, for commercial providers of GPS services to start complaining. Location-based services, after all, are only as good as their actual usefulness—and if you've got a customer lost in the woods, you want that customer to know as precisely as possible where they are so they can get un-lost. In 2000, not that long before he left office, President Clinton got rid of selective availability and freed the world from ever depending on paper maps or confusing directions from relatives again.

GPS has not, however, been a panacea for international conflicts over the positioning of large vehicles. Just a few years ago, in 2007, a group of British sailors were detained by the Iranian government, which said they had wandered into Iranian waters. The British GPS system showed the boats in Iraqi waters. But it didn't matter. According to the Iranian authorities, they had been in Iranian waters. The sailors were released eventually—but only after almost two weeks of discussion over where, exactly, they had been.

SpaceShipTwo's Rocket Engine Did Not Cause Fatal Crash

As reported by Discovery: It wasn't SpaceShipTwo’s hybrid rocket motor -- which was flying on Friday with a new type of fuel -- that caused the fatal crash, the head of the accident investigation agency said late Sunday.

The ship’s fuel tanks and its engine were recovered intact, indicating there was no explosion.
“They showed no signs of burn-through, no signs of being breached,” Christopher Hart, acting chairman of the National Transportation and Safety Board, told reporters at the Mojave Air and Space Port in Mojave, Calif.

Instead, data and video relayed from the ship show its hallmark safety feature -- a fold-able tail section designed for easy re-entry into the atmosphere from space -- was deployed early.

“The engine burn was normal up until the extension of the feathers,” said Hart.

Normally, the feather system wouldn't be unlocked until the rocket-powered spaceship is moving about Mach 1.4, or 1.4 times faster than the speed of sound.

Instead, the co-pilot moved the lever from locked to unlock when the spaceship was traveling at about Mach 1, Hart said.

“I’m not stating that this is the cause of the mishap,” he added. “We have months and months of investigation to determine what the cause was.”

In addition to the possibility of pilot error, Hart said the NTSB is looking into a variety of other issues that may have caused or contributed to the accident, including training, spacecraft design and the safety culture at Virgin Galactic and Scaled Composites, which designed and manufactured the spaceship.

“There is much more that we don’t know and our investigation is far from over,” Hart said.

The accident claimed the life of Scaled Composites test pilot Mike Alsbury, who was serving as the spaceship co-pilot, Scaled’s website shows. Pilot Pete Siebold, who was able to parachute to the ground, survived with a serious shoulder injury.

SpaceShipTwo took off on Friday morning for what was expected to be its fourth powered test flight. It was released as planned from its carrier jet at an altitude of about 45,000 feet. Seconds later, the spaceship’s hybrid motor, which was using a new plastic propellant, powered up.

About nine seconds later, the ship’s feathering system was unlocked, said Hart. Two seconds after that, the ship’s tail section moved toward the deployed position.

"This was an uncommanded feather, which means the feather occurred without the feather lever being moved into the feather position," Hart told Discovery News.
“Shortly after the feathering occurred, the telemetry data terminated and the video data terminated,” he said.

Debris was scattered over a five-mile area north of the spaceport, indicating the spaceship broke apart in flight.

About 800 people already have paid or put down deposits to fly on SpaceShipTwo. Virgin Galactic hoped to begin passenger service next year. The company's second ship is about 65 percent complete.